Convenient device of assembling of gas-cooker
Technical Field
The invention relates to the technical field of novel gas stove assembling structures, in particular to a convenient gas stove assembling device.
Background
The gas-cooker refers to the kitchen utensil that carries out direct fire heating with gaseous fuel such as liquefied petroleum gas (liquid), artifical coal gas, natural gas, and the gas-cooker is called gas-cooker again, stove dish, top of a kitchen range, cooking utensils, need assemble in the gas-cooker production process, consequently need the device of assembling that corresponds, however, current device is not convenient for accomplish the location of assembling the base to the gas-cooker and presss from both sides tightly, and lacks the automatic hammering structure of assembling that corresponds, leads to assembling in-process needs a large amount of manpowers hammering installation.
Disclosure of Invention
The invention aims to provide a convenient assembling device for a gas stove, which solves the existing problems: the existing device is inconvenient to complete the positioning and clamping of the gas stove assembly base.
In order to achieve the purpose, the invention provides the following technical scheme: a convenient assembling device for a gas stove comprises a base carrying plate, wherein two sides of the base carrying plate are fixedly connected with automatic positioning and clamping structures, one end of the base carrying plate is fixedly connected with an outer supporting and positioning block, two sides of one end of the outer supporting and positioning block are fixedly connected with a multidirectional following and adjusting structure, and one side of the top end of the multidirectional following and adjusting structure is fixedly connected with a reciprocating derivation hammering installation structure;
the automatic positioning and clamping structure comprises a supporting and carrying plate, a movable guide output structure, a first folding supporting block, a first clamping push rod, a first matching supporting block and a second clamping push rod, wherein the top end of one side of the supporting and carrying plate is fixedly connected with the movable guide output structure, the output end of the movable guide output structure is fixedly connected with the first clamping push rod, one end of the first clamping push rod is rotatably connected with the first folding supporting block, one end of the first folding supporting block is fixedly connected with the supporting and carrying plate, the other end of the first clamping push rod is rotatably connected with the first matching supporting block, and the top end of the first clamping push rod is rotatably connected with the second clamping push rod.
Preferably, the automatic positioning and clamping structure further comprises an auxiliary guide slide rail, a clamping contact plate, a second folding support block and a second matching support carrier block, wherein one end of a second clamping push rod is rotatably connected with the second folding support block, the other end of the second clamping push rod is rotatably connected with the second matching support carrier block, one side of the second folding support block is welded with the clamping contact plate, the other side of the support carrying plate and one side of the clamping contact plate are both welded with the auxiliary guide slide rail, the top end and the bottom end of the first matching support carrier block and the top end and the bottom end of the second matching support carrier block are both in sliding connection with the auxiliary guide slide rail, and one end of the second folding support block is welded with the clamping contact plate.
Preferably, the movable guide output structure comprises a matching displacement sliding block, a first hydraulic piston cylinder, a stroke driving frame, a derivation connecting rod and an auxiliary positioning base, one end of the auxiliary positioning base is welded with the supporting and carrying plate, the top end of the auxiliary positioning base is slidably connected with the matching displacement sliding block, one side of the matching displacement sliding block is fixedly connected with the first hydraulic piston cylinder through a screw, the output end of the first hydraulic piston cylinder is fixedly connected with the derivation connecting rod, and the stroke driving frame is welded at one end of the matching displacement sliding block.
Preferably, the welding of the outside of deriving the connecting rod has synchronous guide block, the drive spout has all been seted up to the both sides of synchronous guide block, the guide slide rail has all been seted up to the inside both sides of stroke drive frame, the guide slide rail is clearance fit with driving the spout.
Preferably, the multidirectional following adjusting structure comprises a transverse guide frame, a second hydraulic piston cylinder, a synchronous transverse adjusting block, a third hydraulic piston cylinder, an L-shaped displacement supporting plate and a carrying rib plate, wherein the second hydraulic piston cylinder is fixedly connected to one side of the transverse guide frame through a screw, the synchronous transverse adjusting block is fixedly connected to the output end of the second hydraulic piston cylinder, the synchronous transverse adjusting block is slidably connected with the transverse guide frame, the third hydraulic piston cylinder is fixedly connected to one side of the top end of the synchronous transverse adjusting block through a screw, the L-shaped displacement supporting plate is fixedly connected to the output end of the third hydraulic piston cylinder, and the carrying rib plate is welded to the top end of the L-shaped displacement supporting plate.
Preferably, multidirectional following regulation structure still includes first motor, output screw and tutor polished rod, carry on the bottom of floor one end through the first motor of screw fixedly connected with, the output fixedly connected with output screw of first motor, the top of carrying on floor one end still welds the tutor polished rod, the tutor polished rod is located output screw one side, the outside and the reciprocal hammer pressure mounting structure swing joint that derives of output screw and tutor polished rod.
Preferably, reciprocal deduction hammer pressure mounting structure includes synchronous displacement slider, L type location supporting shoe, second motor, torque derivation pole, eccentric entrainment wheel and two-way linkage push rod, the welding of the one end of synchronous displacement slider has L type location supporting shoe, the one end on L type location supporting shoe top is through screw fixedly connected with second motor, the output fixedly connected with torque derivation pole of second motor, torque derivation pole rotates with L type location supporting shoe to be connected, the outside fixedly connected with eccentric entrainment wheel of torque derivation pole, the one end of eccentric entrainment wheel has cup jointed two-way linkage push rod.
Preferably, it is reciprocal to deduce hammering mounting structure and still include the guide stroke post, move the cassette, spring, reciprocating displacement depression bar, piston gasket and tup in coordination, the cassette has been cup jointed to the bottom of two-way linkage push rod, the one end welding of L type location supporting shoe has the guide stroke post, the bottom welding of the cassette of moving in coordination has the reciprocating displacement depression bar, the week side fixedly connected with piston gasket of reciprocating displacement depression bar, the piston gasket is with the inboard sliding connection of guide stroke post, the top fixedly connected with spring of piston gasket, the bottom welding of reciprocating displacement depression bar has the tup.
Preferably, a guide through hole and a power output through hole are formed in the synchronous displacement sliding block, the guide through hole is located on one side of the power output through hole, the power output through hole is in threaded connection with the output screw rod, and the guide through hole is in sliding connection with the auxiliary guide polish rod.
Compared with the prior art, the invention has the beneficial effects that:
1. according to the invention, through the design of the automatic positioning and clamping structure, the device is convenient for completing automatic adaptive deduction and clamping on the assembled base, so that the assembly is convenient to position;
2. according to the invention, through the matching design of the multidirectional following adjusting structure and the reciprocating derivation hammering mounting structure, the device is convenient for completing automatic reciprocating hammering on the assembling position, the manpower output in the assembling and connecting process is reduced, and the use convenience is improved.
Drawings
In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.
FIG. 1 is a schematic structural view of the present invention as a whole;
FIG. 2 is a side view of the present invention in its entirety;
FIG. 3 is a schematic view of a portion of the automated positioning and clamping mechanism of the present invention;
FIG. 4 is a schematic diagram of a partial structure of a power output structure according to the present invention;
FIG. 5 is a partial side view of the present invention;
FIG. 6 is a partial schematic view of the multi-directional follow-up adjustment structure of the present invention;
FIG. 7 is a front view of a multidirectional following adjustment structure of the present invention;
fig. 8 is a partial structural view of the reciprocating derivation hammering mounting structure of the present invention.
In the figure: 1. a base mounting plate; 2. an automatic positioning and clamping structure; 3. an outer support positioning block; 4. a multidirectional following adjustment structure; 5. reciprocating to deduce the hammering installation structure; 6. supporting the carrying plate; 7. a dynamic output structure; 8. a first folding support block; 9. a first clamping ram; 10. a first cooperating support carrier block; 11. a second clamping ram; 12. an auxiliary guide slide rail; 13. clamping the contact plate; 14. a second folding supporting block; 15. a second cooperating support carrier block; 16. a displacement slide block is matched; 17. a first hydraulic piston cylinder; 18. the stroke drives the frame; 19. a derivation connecting rod; 20. an auxiliary positioning base; 21. a lateral guide frame; 22. a second hydraulic piston cylinder; 23. a synchronous transverse adjusting block; 24. a third hydraulic piston cylinder; 25. an L-shaped displacement support plate; 26. carrying a rib plate; 27. a first motor; 28. an output screw; 29. a guide polish rod; 30. a synchronous displacement slider; 31. an L-shaped positioning supporting block; 32. a second motor; 33. a torque lead-out rod; 34. an eccentric driving wheel; 35. a bidirectional linkage push rod; 36. a guide stroke post; 37. matching the clamping seat; 38. a spring; 39. a reciprocating displacement compression bar; 40. a piston shim; 41. a hammer head.
Detailed Description
The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.
Please refer to fig. 1-8:
a convenient assembling device for a gas stove comprises a base carrying plate 1, wherein both sides of the base carrying plate 1 are fixedly connected with automatic positioning and clamping structures 2, one end of the base carrying plate 1 is fixedly connected with an outer supporting and positioning block 3, both sides of one end of the outer supporting and positioning block 3 are fixedly connected with a multidirectional following and adjusting structure 4, and one side of the top end of the multidirectional following and adjusting structure 4 is fixedly connected with a reciprocating derivation hammering mounting structure 5;
specifically, please refer to 3-5:
the automatic positioning and clamping structure 2 comprises a supporting and carrying plate 6, a movable guide output structure 7, a first folding supporting block 8, a first clamping push rod 9, a first matched supporting block 10 and a second clamping push rod 11, the top end of one side of the supporting and carrying plate 6 is fixedly connected with the movable guide output structure 7, the output end of the movable guide output structure 7 is fixedly connected with the first clamping push rod 9, one end of the first clamping push rod 9 is rotatably connected with the first folding supporting block 8, one end of the first folding supporting block 8 is fixedly connected with the supporting and carrying plate 6, the other end of the first clamping push rod 9 is rotatably connected with the first matched supporting block 10, the top end of the first clamping push rod 9 is rotatably connected with the second clamping push rod 11, the automatic positioning and clamping structure 2 further comprises an auxiliary guiding slide rail 12, a clamping contact plate 13, a second folding supporting block 14 and a second matched supporting block 15, one end of the second clamping push rod 11 is rotatably connected with the second supporting block 14, a clamping contact plate 13 is welded at one side of the second folding supporting block 14, a second matching supporting carrier block 15 is rotatably connected at the other end of the second clamping push rod 11, auxiliary guide slide rails 12 are welded at the other side of the supporting and carrying plate 6 and one side of the clamping contact plate 13, the top end and the bottom end of the first matching supporting carrier block 10 and the top end and the bottom end of the second matching supporting carrier block 15 are slidably connected with the auxiliary guide slide rails 12, and one end of the second folding supporting block 14 is welded with the clamping contact plate 13;
the movable guide output structure 7 comprises a matching displacement slide block 16, a first hydraulic piston cylinder 17, a stroke driving frame 18, a derivation connecting rod 19 and an auxiliary positioning base 20, one end of the auxiliary positioning base 20 is welded with the supporting and carrying plate 6, the top end of the auxiliary positioning base 20 is slidably connected with the matching displacement slide block 16, one side of the matching displacement slide block 16 is fixedly connected with the first hydraulic piston cylinder 17 through a screw, the output end of the first hydraulic piston cylinder 17 is fixedly connected with the derivation connecting rod 19, and one end of the matching displacement slide block 16 is welded with the stroke driving frame 18;
a synchronous guide block is welded on the outer side of the derivation connecting rod 19, driving sliding grooves are formed in two sides of the synchronous guide block, guide sliding rails are formed in two sides of the inner portion of the stroke driving frame 18, and the guide sliding rails are in clearance fit with the driving sliding grooves;
the first hydraulic piston cylinder 17 is used for outputting and driving a derivation connecting rod 19 to slide and displace at a stroke driving frame 18, the derivation connecting rod 19 is used for deriving and driving a first clamping push rod 9 to displace, the rotary connection of the first clamping push rod 9 and a first folding supporting block 8 is used for deriving and driving, the synchronous power obtained by a second clamping push rod 11 under the rotary connection of the first clamping push rod 9 and the second clamping push rod 11 is used for leading a second matching supporting carrier block 15 to slide and displace at an auxiliary guiding slide rail 12 through the rotary connection of one end of the second clamping push rod 11 to form the extended reserved stroke driving, and the sliding connection of the first matching supporting carrier block 10 and the auxiliary guiding slide rail 12 is used for forming the extended stable support of the second clamping push rod 11 and the first clamping push rod 9 under the rotary connection of the first clamping push rod 9 and the first matching supporting carrier block 10, the derivation is utilized to enable the clamping contact plate 13 to be displaced to finish the automatic clamping of the gas stove base;
specifically, please refer to 6-8:
the multidirectional following adjusting structure 4 comprises a transverse guide frame 21, a second hydraulic piston cylinder 22, a synchronous transverse adjusting block 23, a third hydraulic piston cylinder 24, an L-shaped displacement supporting plate 25 and a carrying rib plate 26, wherein one side of the transverse guide frame 21 is fixedly connected with the second hydraulic piston cylinder 22 through a screw, the output end of the second hydraulic piston cylinder 22 is fixedly connected with the synchronous transverse adjusting block 23, the synchronous transverse adjusting block 23 is slidably connected with the transverse guide frame 21, one side of the top end of the synchronous transverse adjusting block 23 is fixedly connected with the third hydraulic piston cylinder 24 through a screw, the output end of the third hydraulic piston cylinder 24 is fixedly connected with the L-shaped displacement supporting plate 25, and the carrying rib plate 26 is welded at the top end of the L-shaped displacement supporting plate 25;
the multidirectional following adjusting structure 4 further comprises a first motor 27, an output screw 28 and an auxiliary guide polish rod 29, the bottom of one end of the carrying rib plate 26 is fixedly connected with the first motor 27 through a screw, the output end of the first motor 27 is fixedly connected with the output screw 28, the top of one end of the carrying rib plate 26 is further welded with the auxiliary guide polish rod 29, the auxiliary guide polish rod 29 is positioned on one side of the output screw 28, and the outer sides of the output screw 28 and the auxiliary guide polish rod 29 are movably connected with the reciprocating derivation hammer pressure mounting structure 5;
the reciprocating derivation hammering mounting structure 5 comprises a synchronous displacement slider 30, an L-shaped positioning support block 31, a second motor 32, a torque leading-out rod 33, an eccentric driving wheel 34 and a bidirectional linkage push rod 35, wherein the L-shaped positioning support block 31 is welded at one end of the synchronous displacement slider 30, the second motor 32 is fixedly connected to one end of the top end of the L-shaped positioning support block 31 through a screw, the torque leading-out rod 33 is fixedly connected to the output end of the second motor 32, the torque leading-out rod 33 is rotatably connected with the L-shaped positioning support block 31, the eccentric driving wheel 34 is fixedly connected to the outer side of the torque leading-out rod 33, and the bidirectional linkage push rod 35 is sleeved at one end of the eccentric driving wheel 34;
the reciprocating derivation hammering mounting structure 5 further comprises a guide stroke column 36, a matching clamping seat 37, a spring 38, a reciprocating displacement compression bar 39, a piston gasket 40 and a hammer 41, the matching clamping seat 37 is sleeved at the bottom end of the bidirectional linkage push rod 35, the guide stroke column 36 is welded at one end of the L-shaped positioning support block 31, the reciprocating displacement compression bar 39 is welded at the bottom end of the matching clamping seat 37, the piston gasket 40 is fixedly connected to the peripheral side surface of the reciprocating displacement compression bar 39, the piston gasket 40 is slidably connected with the inner side of the guide stroke column 36, the spring 38 is fixedly connected to the top end of the piston gasket 40, and the hammer 41 is welded at the bottom end of the reciprocating displacement compression bar 39;
the extension of the output end of the second hydraulic piston cylinder 22 is used for driving the synchronous transverse adjusting block 23 to slide under the guide of the transverse guide frame 21, the transverse adjustment of the hammering position of the reciprocating derivation hammering installation structure 5 is completed, the output of the third hydraulic piston cylinder 24 is used for deriving the L-shaped displacement support plate 25 for completing the longitudinal adjustment of the hammering position of the reciprocating derivation hammering installation structure 5, at the moment, the output of the first motor 27 is used for driving the output screw 28 to complete the rotation, because the synchronous displacement slide block 30 is internally provided with a guide through hole and a power output through hole, the guide through hole is positioned at one side of the power output through hole, the power output through hole is connected with the output screw 28 through threads, so that the synchronous displacement slide block 30 obtains torque, the guide through hole is in sliding connection with the auxiliary guide polished rod 29, so that the torque received by the synchronous displacement sliding block 30 is limited to form lifting power, and the hammering installation height of the reciprocating derivation hammering installation structure 5 is convenient to adjust;
when hammering is needed, the second motor 32 is used for driving the torque exporting rod 33 to complete torque output, torque is obtained through connection of the eccentric driving wheel 34 and the torque exporting rod 33, due to the eccentric design of the eccentric driving wheel 34, the eccentric driving wheel 34 has highest point driving and lowest point driving in the rotating process, reciprocating derivation is formed, the reciprocating derivation is transmitted to the matching clamping seat 37 and the reciprocating displacement pressing rod 39 through the bidirectional linkage push rod 35, the hammer head 41 is driven to form hammering through sliding of the reciprocating displacement pressing rod 39 in the guide stroke column 36, and in order to avoid stroke overtravel, the spring 38 is pressurized through sliding of the piston gasket 40 in the guide stroke column 36, and limiting is completed through elasticity of the spring 38.
It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.